on 01-06-2016
Enrique Solano, University of the Basque Country, Bilbao, Spain
01/06/2016, 14:00
Room P3.10, Mathematics Building, IST
I will introduce the concept of embedding quantum simulators, which allow for the implementation of unphysical ope rations in the lab. For instance, the complex conjugation of an unknown quantum state, a forbidden antilinear operation in quantum physics, could be realized via the use of an auxiliary qubit. This opens the possibility for measuring entanglement of an evolving quantum system with few observables and without the necessity of full tomography. Finally, I will explain how to adapt these ideas to different quantum platforms as trapped ions and superconducting circuits, among others.
Quantum Computation and Information Seminar
http://math.tecnico.ulisboa.pt/seminars/qci/index.php.en?action=next
Support: Phys-Info (IT), SQIG (IT), CFIF and CAMGSD, with support from FCT, FEDER and EU FP7, namely via the Doctoral Programme in the Physics and Mathematics of Information (DP-PMI), and projects PEst-OE/EEI/LA0008/2013, QuSim, QUTE-EUROPE (GA 600788) and PAPETS (323901).
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on 20-05-2016
Anthony Leverrier, INRIA Rocquencourt
20/05/2016, 10:00
Room P3.10, Mathematics Building
The ability to distribute secret keys between two parties with information-theoretic security, that is regardless of the capacities of a malevolent eavesdropper, is one of the most celebrated results in the field of quantum information processing and communication. Indeed, quantum key distribution illustrates the power of encoding information on the quantum properties of light and has far-reaching implications in high-security applications. Today, quantum key distribution systems operate in real-world conditions and are commercially available. As with most quantum information protocols, quantum key distribution was first designed for qubits, the individual quanta of information. However, the use of quantum continuous variables for this task presents important advantages with respect to qubit-based protocols, in particular from a practical point of view, since it allows for simple implementations that require only standard telecommunication technology. In this talk, I will explain the principle of continuous-variable quantum key distribution and explain how to prove security for such protocols.
Quantum Computation and Information Seminar
http://math.tecnico.ulisboa.pt/seminars/qci/index.php.en?action=next
Support: Phys-Info (IT), SQIG (IT) and CAMGSD, with support from FCT, FEDER and EU FP7, namely via the Doctoral Programme in the Physics and Mathematics of Information (DP-PMI), and projects PEst-OE/EEI/LA0008/2013, QuSim, and PAPETS (323901).
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